INTEGRATED REMOTE RADIO HEAD AND ANTENNA MODULE ASSEMBLY
A remote radio head assembly attaches a remote radio head to the back wall of an antenna unit. The remote radio head assembly has a radio bracket attached to the top of the radio head having a handle for lifting and carrying the radio head. Radio guide spacers attached to the back side of the remote radio head are for sliding the remote radio head along a mounting rail attachment disposed on the back wall of the antenna unit. The mounting rail has a pivot hook for receiving an installation lever configured to engage with the handle to move the remote radio head in downward and upward directions so as to couple the connector ports of the antenna unit.
This application is a continuation-in-part of pending U.S. patent application Ser. No. 17/978,881, filed on Nov. 1, 2022, the entirety of which is incorporated by reference.
FIELD OF THE INVENTIONThe present invention relates to an assembly for releasably attaching a remote radio head (RRH) to an antenna module of a base station on a telecommunication tower such as a cellular telephone antenna tower.
BACKGROUNDWithin the past few years antenna manufacturers have developed a new approach in placing cellular remote radio heads (RRH) as close as possible to the antenna units of the cell towers. In a few arrangements, the RRH units are attached to the back wall of the antenna unit to minimize the lengths of coaxial cable used to connect the radio to the antenna when they are physically separated. The signal loss over the length of the cable ultimately reduces the amount of power transmitted from the antenna and received by the antenna, reducing its effective range. Integrating the radio with the antenna optimizes the range covered by the antenna. There are also logistical reasons for installing RRH units close to the antenna modules, such as lack of available space to locate a ground-based radio in crowded urban settings, stadiums, etc.
However, because the remote radio head has a sizable dimension and weight, attaching and detaching it from the antenna module of a cell tower requires some effort by the operating technician, demanding an arrangement and design that is as safe and convenient as possible. Although there has been some effort to devise solutions for a safer and easier process for installing the RRH on the antenna module, there is still a need for an ever more convenient arrangement for releasably attaching an RRH to the antenna unit.
SUMMARY OF THE INVENTIONIn accordance with various embodiments of the invention, a remote radio head (RRH) having a frame and a bracket is configured to be slidably and releasably attached to the back wall of an antenna unit of a cellular tower. A guide rail is attached to the back wall for slidably receiving the RRH. The top portion of the RRH bracket includes at least one anchor pin, that is configured to face the back wall of the antenna module when the RRH is slidably and vertically guided along the guide rail. The guide rail includes a slot for receiving an installation lever that has a fork shaped distal end to engage with the anchor pin. The bottom side of the RRH includes radio cable connectors that are configured to connect with the receiving connectors of the antenna module. Once the RRH is guided such that the cable connectors are proximally aligned with the receiving connectors of the antenna module, the operator engages the installation lever through the guide slot such that its fork like distal end engages with the anchor pin. The movement of the installation lever against the pin downwardly forces the RRH cable connectors to engage with the receiving connectors of the antenna module. Conversely, engaging the installation lever in the opposite direction allows the RRH cable connectors to easily disengage upwardly from the antenna module connectors.
In accordance with another embodiment, the RRH cable connector and the connectors of the antenna module include a blind mate arrangement to compensate for any misalignment when they are pressed towards each other. Additionally, the connectors of the antenna module include a spring mechanism so as to receive the RRH cable connectors in a spring-loaded arrangement.
To this end, and in accordance with one embodiment, the connectors in the antenna module are spring loaded. Inside this module there is also a connector stabilizing arrangement, to ensure the connectors stay perpendicular to radio connector face. Furthermore, an alignment cover is provided, that supports the spring and ensures that the spring is applying the force in the correct direction. The spring-loaded connectors in the antenna module are preloaded to ensure the integrity of the radio frequency signal path. The spring-loaded connectors have other benefits in that tolerances can be overcome with a connector that has flexibility in axial and radial directions moving up and down. It also maintains a force on the radio connectors to maintain a robust RF connection through vibration and shock loads on the unit.
In accordance with various embodiments;
The present disclosure may be modified in various embodiments, some of which will be described in more detail here. However, the present disclosure is not limited to the specific embodiments described here, but includes equivalents, and alternatives that are included within the scope of this disclosure. The terms used here are for the purposes of describing specific embodiments and are not intended to limit the scope of the disclosure.
Referring now to
Back wall 90 additionally supports two guide rail modules 112 (only one shown in
In accordance with one embodiment, as illustrated in
As illustrated in
In accordance with one embodiment, at least one of the panels 130 includes a narrow slot 116 at its top portion for receiving an installation lever (not shown) to help an installer to forcibly slide remote radio head 102 downwardly to engage its connector parts 242 with the antenna module connector parts 240 coupled to terminals 120 (
In accordance with one embodiment, top bracket section 126a includes an anchor pin 114, such as a shoulder screw that extends behind the front surface of bracket section 126a as illustrated in
As illustrated in
In accordance with one embodiment, in order to securely place remote radio head 102 against guide rail module 112, panels 130a and 130b include shoulder screw guides or slots 140 at their top and bottom portions that are configured as open slots to receive corresponding shoulder screws 142. In accordance with one embodiment, guide slots 140 include a neck portion that has a diameter that is smaller than the diameter of shoulder screws 142, so that when shoulder screws 142 are slid along guide slots 140 the screw would not move beyond the neck portion without an additional exertion force. However, once a sufficient force is exerted, the neck portion opens allowing the shoulder screws to slide along the remaining portion of slot 140, allowing the shoulder screw to rest against its bottom portion.
Shoulder screws 142 are attached to the sides of remote radio head 102. In one embodiment each side of remote radio head 102 has two shoulder screws 142 at its top and bottom portions corresponding to the location of screw guides 140 so that as the remote radio head is placed against the back side of antenna module and pushed towards the back side the remote radio head is slid downwardly against the side panels 130a and 130b, the shoulder screws sliding into the opening of the screw guides or slots and first resting against its neck portion and eventually moving past the neck portion and towards the base portion of the slots when installation lever 150 exert force downwardly against the remote radio head. In accordance with one embodiment, the shoulder screws are configured to bear some weight of the remote radio head when resting against the base portions of the screw guides, as illustrated in
As further illustrated further in
Referring back to
In accordance with one embodiment as illustrated in
In accordance with one embodiment,
It is noted that although in accordance with one embodiment described above in reference to pin 114 and its location somewhere in the middle of top bracket section 126a, in accordance with other embodiments the location of pin 114 is at any desired point along the width of bracket section 126a, as long as remote radio head is disposed in alignment with connector parts 240 of the antenna module. As it can be appreciated by those skilled in the art, installation lever 150 would exert a vertical force downward or upward regardless of the position of screw 114 along the width of top bracket section. Furthermore, in accordance with other embodiments, more than one pin 114 is employed, and installation lever 150 engages with the screw that is closest to slot 116.
To this end,
In accordance with one embodiment, the connector assembly configured to couple the input/output terminals 120 of the antenna module to the input/output terminals of the remote radio head are a modified spring-loaded blind mate 4.3-10 connector assembly, which is a radio frequency industry standard used in radio frequency systems. Preferably, the push pull type connector is employed in accordance with one embodiment. In a blind-mate connection, for the male and female parts the mating action happens via a sliding or snapping action, with a self-aligning feature that allows for misalignments of the two parts during mating. This feature accommodates for any misalignment between connector parts of remote radio head 102 and connector parts of antenna module 100, when they are juxtaposed near each other as the remote radio head is pushed down towards the connectors of the antenna module as illustrated in more detail in reference to
Each connector part 240 in accordance with one embodiment of the invention is a male part of a blind mate connector such as 4.3-10 connector. Connector part 240 is connected and receives and transmits signals to input/output ports of antenna module 100. As illustrated further in
As illustrated in
In accordance with one embodiment, housing unit 288 and flat surface 296 are made of preferably plastic. Plastic materials are best suited to prevent passive intermodulation from the metal connectors. In accordance with one embodiment, the material chosen is Acrylonitrile Styrene Acrylate (ASA) glass filled material. This has strength, lightweight, UV protection, and moldability. Other plastics compromises would have to be made with UV protection and/or strength.
Referring to
To this end, there are various advantages when the connectors in the antenna module are spring loaded. Support module 290 along with pin 302 ensure an axial and radial alignment with the connectors staying perpendicular to radio connector face, as they remain aligned along base plug 294 and base sleeve 304 functioning as an alignment cover, supporting the spring and ensuring that the spring is applying the force in the correct direction. The spring-loaded connectors in the antenna module are preloaded to ensure solid electrical connection. The spring-loaded connectors have other benefits in that tolerances can be overcome with a connector that has flexibility in moving up and down. Spring 292 maintains a force on the radio connectors to maintain a solid mechanical and RF connection through vibration and shock loads on the unit.
As such,
In some applications coupler 320 is optionally installed, in accordance with one embodiment, to couple off electrical signals from the main electrical path. One side of coupler 320 includes a circular plate with 4 screws and a connector functioning as a coupled port. Typically, if a coupler 320 is installed, the main radio signal travels through the coupler and a small amount of power is coupled off and available at the coupled port for monitoring.
The blind mate connector assembly in accordance with one embodiment, does not have threads and nut for securing the male to female connector parts and is instead stabilized with the spring 292 (
To this end, one difference of the blind mate connector assembly described herein and a standard 4.3-10 is how the mated connection is secured. A standard 4.3-10 female connector has a threaded outer housing which is compatible with a coupling nut on the male connector. The nut screws onto the threads and holds the interface stable.
Distal end 320a of coupler 320 has a length sufficient to allow full contact and engagement with connector part 240 as the remote radio head 102 is moved downwardly with the force exerted by installation lever 150. A connector boot 318 is attached to coupler 320 and covers the distal end 320a of coupler 320, as well as the distal end 288a of connector housing unit 288 as coupler 320 moves towards connector portion 240. To this end, the diameter of proximal portion 318a of connector boot 318 is approximately equal to the diameter of distal portion 320a of coupler 320 to securely surround it as a sleeve, while the diameter of distal portion 318b of connector boot 318 is large enough to cover both distal portion 320a of coupler 320 and distal portion 288a of connector housing 288 as a sleeve. Distal end portion 320a of coupler 320 and the attached connector boot 318 are free to move within and around connector housing 288 as illustrated in
It is noted that in accordance with another embodiment where there is no coupler 320 installed, each connector part 242 has a structure similar to coupler 320 for engagement with connector parts 240. Instead of being attached to coupler 320, connector boot 318 is attached to connector part 240 and covers the distal end of connector part 240. The distal end portion of connector part 240 and the attached connector boot 318 are free to move within and around connector housing 288.
As coupler 320 moves towards portion 288a, spring support 290 exerts a force against spring 292 causing the spring to move from its relaxed position or preferably preloaded position to a compressed position. Meanwhile, pins 270, 272 of connector part 242 couple to pins 264, 266 of connector part 240 when the two connector parts of the blind mate assembly are pressed against each other. As remote radio head 102 is forced down against connector part 240, spring 292 compresses downwardly, allowing its stored compression to releasably push back connector part 240 when remote radio head 102 is pulled back up from its connection to antenna module 100.
To this end,
In accordance with another embodiment,
As further illustrated in
As illustrated in
At this point, corresponding pins 482 of retractable plungers 456 are pushed into the corresponding holes 504 and the antenna module connectors are fully engaged with the connectors of remote radio heads 402 and 404 in a blind mate arrangement.
While only certain features of the invention have been illustrated and described herein, many modifications, substitutions, changes, or equivalents will now occur to those skilled in the art. It is therefore, to be understood that this application is intended to cover all such modifications and changes that fall within the true spirit of the invention.
Claims
1. A remote radio head assembly configured to attach a remote radio head to the back wall of an antenna unit said remote radio head assembly comprising:
- a handle coupled to the top of said remote radio head having a handle for handling said remote radio head, said top bracket having at least one radio guide spacer coupled to the back wall of said remote radio head;
- a mounting rail module having an upper and lower guide rail attached to the back wall of said antenna unit and separated from each other at a distance for sliding said radio guide spacer along said mounting rail module; and
- a pivot hook fixedly disposed in relation to said back wall of said antenna unit configured to receive an installation lever that engages with said pivot hook and said handle of said top bracket to push said remote radio head in an upward and downward direction.
2. The remote radio head assembly in accordance with claim 1, wherein said installation lever has a forked shaped distal end.
3. The remote radio head assembly in accordance with claim 2, wherein said handle is attached to a top bracket section coupled to the top portion of said remote radio head.
4. The remote radio head assembly in accordance with claim 3, wherein said pivot hook is attached to the top side of said upper guide rail of said mounting rail module in a location along the projected width of said handle of said top bracket so as to allow said handle to function as a fulcrum for said installation lever.
5. The remote radio head assembly in accordance with claim 4, wherein said top bracket further includes a retractable plunger configured to remain in a retracted position when said remote radio head slides along said mounting rail module, said retractable plunger is released when said remote radio head is positioned to be forced in a downward direction.
6. The remote radio head assembly in accordance with claim 5, wherein said plunger locks into a hole located on said mounting rail module when said remote radio head is pushed downwardly at its intended location.
7. The remote radio head assembly in accordance with claim 3, wherein said mounting rail module accommodates two remote radio heads each sliding from one end of said mounting rail module towards its center.
8. The remote radio head assembly in accordance with claim 3, wherein said lower guide rail of said mounting rail module includes a guide slot and said radio guide spacer includes a vertical plate that slides into said guide slot when said remote radio head is pushed downward.
9. The remote radio head assembly in accordance with claim 8, wherein said lower guide rail has at least two guide slots for receiving corresponding vertical plates of radio guide spacers.
10. The remote radio head assembly in accordance with claim 4, wherein said radio guide spacer includes a front and back plate configured to engage the front walls of said upper and lower guide rails of said rail mounting module in a sliding arrangement.
11. The remote radio head assembly in accordance with claim 10, wherein said radio guide spacer includes a T-shaped plate having a horizontal and vertical plates, said vertical plate having a width configured to engage said guide slots in a friction fit arrangement.
12. The remote radio head assembly in accordance with claim 11, wherein said vertical plate of said radio guide spacer is configured to slide in a corresponding guide slot upon exertion of a force sufficient to widen said guide slot allowing said vertical plate to pass through.
13. The remote radio head assembly in accordance with claim 12, further comprising remote radio head connector parts coupled to input/output terminals of said remote radio head.
14. The remote radio head assembly in accordance with claim 13, wherein said remote radio head connector parts are one of a male connector portion of a blind mate connector.
15. The remote radio head assembly in accordance with claim 14, wherein said remote radio head connector parts are aligned so as to engage with a female connector portion of said blind mate connector, said female connector portion coupled to input/output terminals of said antenna unit.
16. The remote radio head assembly in accordance with claim 15, wherein said blind mate connector fully engages upon said installation lever forcing said remote radio head downwardly along said guide rail.
Type: Application
Filed: Sep 20, 2023
Publication Date: May 2, 2024
Inventors: Gerald Towne (Salem, NH), Jaron Peters (Danville, NH), Vinay Vij (Kanagawa)
Application Number: 18/471,287